KR20100086631A - Apparatus and method for channel auto configuration - Google Patents

Abstract

PURPOSE: A system and a method for automatically setting a channel are provided to perform automatic channel setting of the slave node when installing a slave node or changing master node channel information in a mobile communication system, thereby increasing the convenience of operating communication network and reducing the cost of operation. CONSTITUTION: A modem(710) performs communication with a master node. A slave slot manager(740) changes a time slot in a range which is changeable and inspects the opening of LCP session at the same time. If the LCP session is opened, the slave slot manager performs IPCP connection. A master slot manager uses the set time slot to inspect opening of the LCP session. If the LCP session is opened, the master slot manager performs the IPCP connection.

Description

Apparatus and method for automatic channel configuration {APPARATUS AND METHOD FOR CHANNEL AUTO CONFIGURATION}

The present invention relates to an apparatus and a method for automatically completing a channel setting by automatically searching for a corresponding setting in a slave node when setting only the master node does not need to set channel information for supporting the fractional T1.

For efficient use of the E1 / T1 link, one of the backbone communication lines, the Fractional E1 / T1 (Fractional E1 / T1) function is generally used.

The Fractional E1 / T1 function is a medium for the physical circuit stream, which uses 24 time slots for the T1 and 32 time slots for the E1 without using the total time slots. Indicates.

If the communication data is small, a single T1 line can be shared by multiple service providers (or users), thereby increasing the efficiency of the link and reducing the cost of the service provider.

However, in order to support Fractional T1, it is necessary to share configuration information (time slot number and number) for the fractional channel used by both communication nodes.

1 is a diagram illustrating a general channel setting process.

Referring to FIG. 1, in a mobile communication system, a core network device (master node, hereinafter referred to as master node) 110 and an access device (hereinafter, referred to as slave node) 150 are T1 networks ( Assuming that the connection is performed at 130), both nodes must be set according to predetermined channel information during initial operation to enable communication.

T1 network 130 is composed of a time slot switch, a multiplexer, a repeater. The transmitting node (master node) 110 transmits data to the T1 network through a predefined T1 time slot (channel). The data included in the time slot is transmitted from the repeater of the T1 network 130 to the next device, and the time slot switch of the T1 network 130 changes a specific time slot to another preset time slot. The multiplexer of the T1 network 130 combines and transmits data contained in multiple T1 time slots into one T1 (multiple pairs on one long distance line for efficiency of T1 use in inter-node communication requiring a small amount of time slots). Is used to support inter-node communication of nodes).

The receiving node (slave node) 150 receives data from the T1 network 130 through a predefined time slot.

In order to communicate between nodes, each node must know in advance which time slot should transmit and receive data through the T1 network 130, and set channel information to enable transmission and reception at a predetermined time slot. .

2 is a diagram illustrating a general channel setting change process.

Referring to FIG. 2, assuming that the master node 210 and the slave node 250 are connected to the T1 network 230 in the mobile communication system, both nodes must be set according to predetermined channel information during initial operation. It is possible.

The master node 210 is located in the office where the operator resides, but the slave node 250 is often installed in a place that is difficult for the operator to easily access and also frequently installs multiple slave nodes at the same time.

In the case of using the fragmentation T1, the operator needs to change the channel of the master node 210 during the initial installation of the slave node 250 or when the slave node 250 is operated. You need to find out and set it.

However, this requires a manual setting and there is a problem in that the channel setting is not made when the manual setting is not performed. Therefore, there is a need for an apparatus and method for automatically setting changes at initial installation or when changing channels during operation.

An object of the present invention is to provide an apparatus and method for automatic channel setting.

Another object of the present invention is to enable the automatic setting of the channel of the slave node when the slave node is installed or the master node channel information is changed in the mobile communication system, even if the installer or the operator does not acquire detailed knowledge about setting the slave node channel information. The present invention provides an apparatus and a method for increasing communication network ease of operation and reducing operating costs by enabling communication between nodes and slave nodes.

According to a first aspect of the present invention for achieving the object of the present invention, a process for checking whether a link control protocol (LCP) session is opened while changing a time slot within a changeable range in a channel setting method in a slave node; When the LCP session is opened, characterized in that it comprises the step of performing an Internet Protocol Control Protocol (IPCP) connection.

According to a second aspect of the present invention for achieving the object of the present invention, the process of checking whether the LCP session is opened using the time slot set in the channel configuration method in the master node and the IPCP connection process when the LCP session is opened It characterized in that it comprises a process of performing.

According to a third aspect of the present invention for achieving the object of the present invention, in a device of a slave node that performs channel setup, a communication modem for communicating with a master node and an LCP session are changed while changing time slots within a changeable range. It is characterized in that it comprises a slave slot management unit for checking whether the open and the LCP session is opened to perform an IPCP connection.

According to a fourth aspect of the present invention for achieving the object of the present invention, in the apparatus of the master node to perform channel establishment, checking whether an LCP session is opened by using a communication modem for communicating with a slave node and a set time slot, It characterized in that it comprises a master slot management unit for performing the IPCP connection when the LCP session is opened.

The present invention enables the automatic setting of the channel of the slave node when the slave node is first installed or when the master node channel information is changed, so that the communication between the master node and the slave node is possible even if the installer or the operator does not acquire detailed knowledge about setting the slave node channel information. It is possible to increase the ease of network operation and to reduce the operating cost.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Hereinafter, the present invention will be described an apparatus and method for automatic channel setting.

3 is a diagram illustrating a channel setting process according to an embodiment of the present invention.

Referring to FIG. 3, the master node 310 waits for channel establishment with the slave node 350 through the T1 network 330.

The slave node 350 drives a program for channel setting. The program attempts to connect while changing a slot in order to establish a Link Control Protocol (LCP) connection with the master node 310 during a connection process using a Point to Point Protocol (PPP).

LCP provides the function of performing link establishment monitoring and authentication, and provides the function by exchanging LCP packets between nodes. LCP packet communication is also possible after channel information between nodes is set. That is, when LCP packet communication is possible, that is, the LCP connection is established, indicating that the channel information is set correctly.

When the LCP connection is completed, the slave node 350 starts a network control protocol (NCP) connection process, and initiates a connection using an IPCP (Internet Protocol Control Prtocol), which is one of the NCPs, to perform an IP allocation process.

The IPCP operates after the session is opened through the LCP, and provides functions such as IP address allocation. The slave node is assigned an IP address through the IPCP.

4 is a diagram illustrating a channel setting change process according to an exemplary embodiment of the present invention.

Referring to FIG. 4, the master node 410 waits for channel setting with the slave node 450 when a channel change is performed during communication with the slave node 450 through the T1 network 430.

The slave node 450 drives a program for channel setting. The program attempts to connect while changing slots in order to make LCP connection with the master node 410 during the connection process using PPP.

When the LCP connection is completed, the slave node 450 starts the NCP connection process, and starts the connection using IPCP, which is one of the NCPs, to perform the IP allocation process.

5 is a flowchart illustrating an operation process of a slave node according to an embodiment of the present invention.

Referring to FIG. 5, the slave node starts the LCP connection during the PPP connection process for channel establishment. The master node is waiting for the LCP connection during the PPP connection process to establish the channel.

At the start of the LCP connection, the slave node sets the start slot and the last slot to 0 (step 510). The LCP connection is attempted using the set starting slot and last slot values (step 520) and waits for a predetermined time (about 10 seconds) (step 530).

Thereafter, when the LCP connection using the set start slot and last slot values is successful, that is, when the LCP session is opened (step 540), the IPCP connection is started (step 550) and the IP allocation process is performed (step 560).

If the LCP connection fails using the set start slot and the last slot value, that is, in case of failing to open the LCP session (step 540), it is checked whether the set last slot value is the last slot value (for example, 23) among the slot values.

If the set last slot value is the last slot value (for example, 23) among the slot values (step 545), the channel is set (channel group setting) by resetting the set last slot value to 0 (step 549) ( In step 535, the LCP connection is attempted using the slot value set in this manner (step 520). The above process is repeated.

If the set last slot value is not the last slot value (e.g., step 23) among the slot values (step 545), increase the set last slot value by one (step 547) to set the channel (set a channel group) ( In step 535, the LCP connection is attempted using the slot value thus set (step 520), and the subsequent process is repeated.

Here, the slot represents a time slot. In addition, it is assumed that the start slot value is initially set, and may be set to a different value at the initial setting, but does not change during algorithm operation.

Also, the reason why the last slot value from the beginning to the end is repeated is to deal with an exceptional situation, in case the master node is in an exceptional situation and cannot respond.

6 is a flowchart illustrating an operation process of a master node according to an embodiment of the present invention.

Referring to FIG. 6, the master node sets a corresponding slot for connection as in FIG. 5 (step 610). That is, the start slot and the last slot are set to predetermined values.

Thereafter, when the LCP session with the slave node is opened in the corresponding slot (step 620), an IPCP connection process is performed in the corresponding slot (step 630) and an IP is assigned to the slave node (step 640).

7 is a block diagram of a slave node according to an embodiment of the present invention.

Referring to FIG. 7, the slave node includes a communication modem 710, a controller 720, a storage unit 730, and a slave slot manager 740. The slave slot manager 740 includes an LCP unit 750 and an IPCP unit 760.

The communication modem 710 is a module for communicating with other nodes, and includes a wired processor and a baseband processor. The wired processor converts a signal received through a wired path into a baseband signal and provides the baseband signal to the baseband processor, and converts the baseband signal from the baseband processor to a wired signal so as to be transmitted on an actual wired path. Send via the path.

The controller 720 controls the overall operation of the slave node. In particular, the slave slot manager 740 is controlled according to the present invention.

The storage unit 730 stores a program for controlling the overall operation of the slave node and temporary data generated during program execution.

The LCP unit 750 sets the start slot and the last slot to 0 at the start of the LCP connection, attempts an LCP session connection using the set start slot and last slot values, and waits for a predetermined time.

The LCP unit 750 notifies the slave slot manager 740 when the LCP connection using the set start slot and last slot values is successful, that is, when the LCP session is opened. Thereafter, the slave slot manager 740 instructs the IPCP unit 760 to perform an IPCP connection process.

The LCP unit 750 checks whether the set last slot value is the last slot value (eg, 23) among the slot values when the LCP connection fails using the set start slot and last slot values, that is, when the LCP session fails to open. .

If the set last slot value is the last slot value (for example, 23) among the slot values, the LCP unit 750 resets the set last slot value to 0 to set a channel (set a channel group). Attempt the LCP connection using the set slot value and repeat the following process.

If the set last slot value is not the last slot value (for example, 23) among the slot values, the LCP unit 750 increases the set last slot value by one and sets a channel (sets a channel group). Attempt the LCP connection using the slot value.

The IPCP unit 760 starts an IPCP connection under the control of the slave slot manager 740 and performs an IP allocation process.

In the above-described block configuration, the controller 720 may perform a function of the slave slot manager 740. In addition, the slave slot manager 740 may perform all or part of the functions of the LCP unit 750 and the IPCP unit 760.

When the product is actually implemented, all of the functions of the slave slot management unit 740 may be configured to be processed by the controller 720, and only some of the functions may be configured to be processed by the controller 720.

8 is a block diagram of a master node according to an embodiment of the present invention.

Referring to FIG. 8, the master node includes a communication modem 810, a controller 820, a storage 830, and a master slot manager 840. The master slot manager 840 includes an LCP unit 850 and an IPCP unit 860.

The communication modem 810 is a module for communicating with other nodes and includes a wired processor and a baseband processor. The wired processor converts a signal received through a wired path into a baseband signal and provides the baseband signal to the baseband processor, and converts the baseband signal from the baseband processor to a wired signal so as to be transmitted on an actual wired path. Send via the path.

The controller 820 controls the overall operation of the master node. In particular, the master slot manager 840 is controlled according to the present invention.

The storage unit 830 stores a program for controlling the overall operation of the master node and temporary data generated during program execution.

That is, the LCP unit 850 sets the start slot and the last slot to a predetermined value. Thereafter, the LCP unit 850 notifies the access slot manager 840 when an LCP session with a slave node is opened in the corresponding slot. Thereafter, the access slot manager 840 instructs the IPCP unit 860 to perform an IPCP connection process.

The IPCP unit 860 initiates an IPCP connection and performs an IP allocation process. That is, an IP address is assigned to the slave node.

In the above-described block configuration, the controller 820 may perform a function of the master slot manager 840. In addition, the master slot manager 840 may perform all or part of the functions of the LCP unit 850 and the IPCP unit 860.

In the case of actually implementing a product, all of the functions of the master slot management unit 840 may be configured to be processed by the controller 820, and only some of the functions may be configured to be processed by the controller 820.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

1 is a diagram illustrating a general channel setting process;

2 is a diagram illustrating a general channel setting change process;

3 is a view illustrating a channel setting process according to an embodiment of the present invention;

4 is a diagram illustrating a channel setting change process according to an embodiment of the present invention;

5 is a flowchart illustrating an operation process of a slave node according to an embodiment of the present invention;

6 is a flowchart illustrating an operation process of a master node according to an embodiment of the present invention;

7 is a block diagram of a slave node according to an embodiment of the present invention; and

8 is a block diagram of a master node according to an embodiment of the present invention.

Claims (4)

In the channel setting method in the slave node, Checking that the Link Control Protocol (LCP) session is open while changing the time slot within the changeable range, If the LCP session is opened, performing an Internet Protocol Control Protocol (IPCP) connection. In the channel setting method in the master node, Checking whether the LCP session is opened using the configured time slot, When the LCP session is opened, performing an IPCP connection. In the device of the slave node to perform the channel setting, A communication modem for communicating with the master node, And a slave slot manager configured to check whether an LCP session is opened while changing a time slot within a changeable range, and perform an IPCP connection when the LCP session is opened. In the apparatus of the master node to perform the channel setting, A communication modem for communicating with a slave node, And a master slot manager configured to check whether an LCP session is opened by using a set time slot, and perform an IPCP connection when the LCP session is opened.

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